Electrophoretic deposition of graphene-based materials: A review of materials and their applications

Ma, Yuhong; Han, Jiemin; Wang, Mei; Chen, Xuyuan; Jia, Suotang

doi:10.1016/j.jmat.2018.02.004

Cited by 120 publications

(80 citation statements)

References 92 publications

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“…In this respect, EPD is useful to develop specific microstructures from multicomponent suspensions [14]; for instance, in the study of PEEK/MoS 2 coatings by electrophoretic codeposition, MoS 2 was found to align preferentially, parallel to the coating surface [15]. Similar preferential alignment of graphene oxide (GO) nanosheets has been reported in the EPD process [16][17][18][19][20][21]. Furthermore, the incorporation of GO has two main advantages: firstly, the adhesion of GO coatings on metallic substrates after thermal treatment has been attributed to the interaction between the oxygenated functional groups of GO and the metallic surface, and thereby, GO coatings have been used as the interface between PEEK and the metallic substrate to enhance the mechanical properties [21]; secondly, p-conjugated structures in graphitic materials can form strong p-p stacking interactions with the benzene ring such that found in PEEK [22,23].…”

Section: Introductionmentioning

confidence: 78%

“…Alignment of GO nanosheets, as result of EPD, has been discussed in the literature [17][18][19][20]. One explanation is that the basal plane will align to the direction of the applied electric field during EPD due to the anisotropic polarizability of the GO nanosheets; another possibility is that the GO aligns parallel to the substrate either due to rotation during deposition or due to capillary effects during drying.…”

Section: Peek/go Coatingsmentioning

confidence: 99%

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Nanocomposite coatings obtained by electrophoretic co-deposition of poly(etheretherketone)/graphene oxide suspensions

et al. 2020

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Nanocomposite coatings were successfully prepared by electrophoretic deposition of poly(etheretherketone) (PEEK)/graphene oxide (GO) suspensions. The GO flakes developed a large-scale co-continuous morphology with the basal plane mainly aligned with the coating surface. However, the PEEK particles were also found to be wrapped by GO nanosheets when deposited on the stainless steel substrate. Both phenomena, the co-continuous morphology and the wrapping effect, were dependent on the initial GO content in the suspension and influenced the final morphological characteristics of the thermally treated coatings. The PEEK matrix developed a dendritic morphology during its cooling from the molten state because of transcrystallinity that was induced by the incorporation of GO. The preparation of suspensions involved tip ultrasonication (TS) to deagglomerate, disperse, and mill the PEEK particles. A detailed study of the microstructure revealed that TS tended not only to reduce PEEK particle size, but also to promote an elongated shape, favourable for the nanocomposite coatings.

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Section: Introductionmentioning

confidence: 78%

Section: Peek/go Coatingsmentioning

confidence: 99%

Nanocomposite coatings obtained by electrophoretic co-deposition of poly(etheretherketone)/graphene oxide suspensions

et al. 2020

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“…This process consists of two electrodes and a suspension of well‐dispersed particles. When the electric field is applied between electrodes, the particles move toward electrodes in opposite direction and deposited on the respective substrate, as shown in Figure . The versatility of this technique for fabrication of ultrathin separators from the colloidal suspension is owing to its high deposition rate, high uniformity, the controllable thickness of membranes, stoichiometry, and dimensionality at low processing cost, efficient control over structure, simple setup, and limited restriction for selection of electrode shape.…”

Section: Separator Preparation Methodologiesmentioning

confidence: 99%

Recent Development in Separators for High‐Temperature Lithium‐Ion Batteries

Waqas

Ali

Feng

et al. 2019

Small

186

121

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metric tons of carbon dioxide (CO 2 ) and other pollutants per year, which accelerate global warming and major climate changes. [2] In order to mitigate these serious issues caused by fossil fuels and to compete with the energy generating devices based on fossil fuels, renewable energy sources like solar energy, wind energy, bioenergy, and geothermal energy are potential alternative power resources. However, these renewable energy resources need highly efficient energy storage devices for integrating and well distribution of energy. Rechargeable battery technology with high energy, high power density, long life cycle capability, fast cycling rate, and reasonable cost is the possible solution to store energy obtained from these renewable sources. [3] Among many rechargeable energy storage devices, lithium-ion batteries (LIBs) are the promising energy sources for integrating renewable resources and high power applications, owing to high energy density, lightweight, high flexibility, slow self-discharge rate, high rate charging capability, long battery life, and environmental benignity. [4,5] The aforementioned attractive properties of rechargeable LIBs promote its utilization in the wide range of applications like laptops, cell phones, electric vehicle, hybrid electric vehicles, renewable power stations, stationary electric power, defense arsenal, subsurface exploration, thermal reactors, and space vehicles. [6][7][8][9] From the last 30 years, rapid development has been observed in LIBs technology. Presently, LIBs hold twofold energy density as compared to the first commercial LIBs developed by Sony in 1991, but still, there are some challenges associated with LIBs that need to be solved for achieving high power density and efficient performances at high and low temperatures. Safety, cost, and enhancement in energy and power densities are the major concerns in next generation LIBs. [10][11][12] Separator is one of the important components of LIBs that is not directly involved in the electrochemical reaction, however, its properties, structure, and composition greatly influence the performance of batteries with respect to internal resistance, long cycle performances, high capacity, and safety. [13] The basic functions of the separator are to prevent the contact between anode and cathode to avoid internal short circuits, store liquid electrolyte, and permit the migration of ions during the chargedischarge process. [14][15][16] The ideal separator should possess Lithium-ion batteries (LIBs) are promising energy storage devices for integrating renewable resources and high power applications, owing to their high energy density, light weight, high flexibility, slow self-discharge rate, high rate charging capability, and long battery life. LIBs work efficiently at ambient temperatures, however, at high-temperatures, they cause serious issues due to the thermal fluctuation inside batteries during operation. The separator is a key component of batteries and is crucial for the sustainability of LIBs at high-temperatures. Th...

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“…In recent years, the use of graphene has been applied to a variety of fields, including optoelectronics, energy storage, electronics as well as biomedical applications [20][21][22][23][24]. In many of these fields, the control of an appropriate macroscopic and microscopic structure is often of paramount importance, if not the limiting factor, in order to satisfy stringent and often contrasting technical requirements.…”

Section: Graphene and Derivatives Propertiesmentioning

confidence: 99%

Additive manufacturing high performance graphene-based composites: A review

Feng

Huang

et al. 2019

Composites Part A: Applied Science and Manufacturing

131

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Electrophoretic deposition of graphene-based materials: A review of materials and their applications

Cited by 120 publications

References 92 publications

Nanocomposite coatings obtained by electrophoretic co-deposition of poly(etheretherketone)/graphene oxide suspensions

Nanocomposite coatings obtained by electrophoretic co-deposition of poly(etheretherketone)/graphene oxide suspensions

Recent Development in Separators for High‐Temperature Lithium‐Ion Batteries

Additive manufacturing high performance graphene-based composites: A review

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